Aromatic carbonyl compounds, hydroxylation

BenzOfurans from o-Hydroxylated Aromatic Carbonyl Compounds and Ethyl Bromomalonate... 

Aromatic hydroxylations of any kind tend to be unsuccessful because the phenol produced is more reactive than the reactant, ArH. In this case, however, only the trifluoroacetate ester, Ar02CCF3, is present in the electrolysis mixture, and it is less reactive than the original ArH. One of the more interesting aspects of this reaction is that aromatic carbonyl compounds can be hydroxylated preferentially ortho, para in contrast to their normal meta directing character. 

Coupling reactions of indoles and carbonyl compounds (either intra- or intermolecularly) have been described. This is a new method for hydroxylation at the C2 position of indole (Scheme 36). The role of HMPA is crucial to prevent reduction or pinacolic coupling of aromatic carbonyl compounds [80]. 

Condensation of salicylaldehyde and its derivatives with a variety of esters of chloroacetic acids in the presence of TBAB led to the synthesis of benzo[b]furans by means of a solid-liquid PTC reaction under the action of microwave irradiation [39]. This was a modification of one of the most popular routes to substituted benzo[b]furans, i.e. O-alkylation of O-hydroxylated aromatic carbonyl compounds with a-halogenated carbonyl compounds then intramolecular condensation. The mixture of aldehydes and chloroacetic acid esters were absorbed on potassium carbonate then irradiated in an open vessel in a domestic MW oven for 8-10 min (Eq. 26). 

PE Unsaturations, aromatic carbonyl compounds, hydrogen at tertiary carbon, aromatic amines, groups formed during oxidation (hydroperoxides, carbonyl, carboxyl, hydroxyl), benzophenones, quinones, transition metal compounds, TiOs, polynuclear aromatics Free radiceds, crosslinks Free radicals, hydroperoxides, carbonyl groups, chain scissions... 

The Diacel columns can be used for the separation of a wide variety of compounds, including aromatic hydrocarbons having hydroxyl groups, carbonyls and sulfoxides, barbiturates, and P-blockers (35,36). There are presendy nine different cellulose derivative-based columns produced by Diacel Chemical Industries. The different columns each demonstrate unique selectivities so that a choice of stationary phases is available to accomplish a separation. 

As discussed in Section 4.01.5.2, hydroxyl derivatives of azoles (e.g. 463, 465, 467) are tautomeric with either or both of (i) aromatic carbonyl forms (e.g. 464,468) (as in pyridones), and (ii) alternative non-aromatic carbonyl forms (e.g. 466, 469). In the hydroxy enolic form (e.g. 463, 465, 467) the reactivity of these compounds toward electrophilic reagents is greater than that of the parent heterocycles these are analogs of phenol. 

The remaining aromatic oximes are primarily a collection of hydroxyl- and methyl-substituted acetophenones and benzaldehydes. Thwarting a comprehensive analysis is a lack of data for the corresponding carbonyl compounds or even deoximated compounds. A comparison of the benzaldoximes with benzaldehydes would be interesting, except there... 

Oxidation/hydroxylation of aromatic compounds by OH and HOONO is expected to enhance their degradation rate and hence decrease their lifetime on particulate matter, which in the case of pollutants is beneficial from the point of view of human health. Oxidation of PAHs could also lead to the production of photosensitizers such as quinones and aromatic carbonyls [10, 40, 41]. These compounds, if present in the gas phase, are also able to form aggregates and are therefore involved in the formation of secondary organic aerosol [42]. In contrast, nitration induced by OH + N02 or HOONO could lead to highly mutagenic nitro-PAHs [43] or phytotoxic nitrophenols [44, 45], in which case the health and environmental impact of the reaction intermediates is not negligible and is sometimes higher than that of the parent molecules. 

Sodium dichromate hydroxylates tertiary carbons [620] and oxidizes methylene groups to carbonyls [622, 623, 625, 626, 631] methyl and methylene groups, especially as side chains in aromatic compounds, to carboxylic groups [624, 632, 633, 634, 635] and benzene rings to quinones [630, 636, 637] or carboxylic acids [638]. The reagent is often used for the conversion of primary alcohols into aldehydes [629, 630, 639] or, less frequently, into carboxylic acids or their esters [640] of secondary alcohols into ketones [621, 629, 630, 641, 642, 643, 644] of phenylhydroxylamine into nitroso-benzene [645] and of alkylboranes into carbonyl compounds [646]. 

The spectrum of applications of potassium permanganate is very broad. This reagent is used for dehydrogenative coupling [570], hydrox-ylates tertiary carbons to form hydroxy compounds [550,831], hydroxylates double bonds to form vicinal diols [707, 296, 555, 577], oxidizes alkenes to a-diketones [560, 567], cleaves double bonds to form carbonyl compounds [840, 842, 552] or carboxylic acids [765, 841, 843, 845, 852, 869, 872, 873, 874], and converts acetylenes into dicarbonyl compounds [848, 856, 864] or carboxylic acids [843, 864], Aromatic rings are degraded to carboxylic acids [575, 576], and side chains in aromatic compounds are oxidized to ketones [566, 577] or carboxylic acids [503, 878, 879, 880, 881, 882, 555]. Primary alcohols [884] and aldehydes [749, 868, 555] are converted into carboxylic acids, secondary alcohols into ketones [749, 839, 844, 863, 865, 886, 887], ketones into keto acids [555, 559, 590] or acids [559, 597], ethers into esters [555], and amines into amides [854, 555] or imines [557], Aromatic amines are oxidized to nitro compounds [755, 559, 592], aliphatic nitro compounds to ketones [562, 567], sulfides to sulfones [846], selenides to selenones [525], and iodo compounds to iodoso compounds [595]. 

In each of the cases you have met so far, we have used a functional group present in the molecule to help us to disconnect the C-C bond using a 1,2 C-C disconnection. You can look for 1,2 C-C disconnections in alkynes, carbonyl compounds, and alkylated aromatic rings. And, if the target isn t a carbonyl compound, consider what would be possible if functional groups such as hydroxyl groups were converted to carbonyl groups (just as we did with belfosdil). 

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